Abstracts for AMS Special Session Ring Structures in the Schubert Calculus 2002 Fall AMS Eastern Section Meeting Northeastern University, Boston, MA October 5-6, 2002

We present a geometric proof of the Horn Conjecture and obtain the Saturation conjecture for Gl(n) as a consequence. The Horn conjecture says that non vanishing of Littlewood-Richardson numbers c^l_m,n is equivalent to the semi-stability of a certain N-filtered vector space (for generic flags). Knutson-Tao gave combinatorial proofs of the Saturation conjecture using the theory of Honeycombs. Fulton showed that Saturation implies the Horn Conjecture. Our proof here is independent of these previous works and raises interesting questions on the Quantum analogues of the Horn Conjecture.
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Soergel has recently shown that knowledge of torsion in the intersection cohomology of Schubert varieties leads to information about modular representation theory. In particular, he has asked what is the smallest N > 0 for which the decomposition theorem holds with coefficients in Z[1/N] for a given Bott-Samelson resolution X --> X_w of a Schubert variety X_w. This implies that there is no Z/pZ-torsion in the intersection cohomology stalks of X_w for p|N. We describe certain polynomials representing a basis for the equivariant cohomology H^*_T(X) which can be used to calculate N. We present examples in types A₇ and D₄ for which N > 1.
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Universal Schubert polynomials, which give the answer to a degeneracy locus problem, specialize to quantum and ordinary Schubert polynomials. I present a Pieri-type formula in some special cases.
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We reframe the question of equivariant Schubert calculus of complete flag varieties in terms of Bott-Samelson manifolds, desingularizations of the flag varieties. In particular, there is a more general algebra related to the equivariant cohomology ring of a Bott-Samelson sitting over a Schubert variety, and we show how to multiply in this algebra. One result is a non-positive formula (and geometric interpretation thereof) for Schubert calculus. The same formula was discovered combinatorially by Sara Billey. Although this is not a positive calculus, there are restricted cases in which it gives a positive formula. Perhaps more interestingly, it sheds light on some geometry behind Schubert calculus. The work we present is joint with Allen Knutson. Some of it was independently discovered by Mathieu Willems (and can be found on the math archives).
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The action of a complex torus on a non-singular projective variety is a GKM action if there are finitely many fixed points and finitely many one-dimensional orbits. For such an action the fixed points and one-dimensional orbits can be viewed as the vertices and edges of a regular graph, and Goresky, Kottwitz and MacPherson showed that the equivariant cohomology ring of the space can be read off from this graph. In this talk we show that an analogous result is true for "GKM spaces with non-isolated fixed points". The work I will report on is joint with Tara Holm.
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Quantum Schubert calculus exhibits a number of symmetries which lead to equalities of certain Gromov Witten invariants, mainly a Z/n action and an involution related to complex conjugation. We analyze the structure of these symmetries and give applications to quantum Schubert calculus.
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We derive a recurrence on Schubert structure constants from the noncomplex Weyl group action on G/B. It is occasionally positive; for example it computes

We construct a flat degeneration of the flag manifold to the toric variety Y associated to the Gel'fand-Cetlin polytope. Every Schubert variety X_w degenerates to a reduced union of toric subvarieties of Y, generalizing results of Gonciulea and Lakshmibai. The faces of the Gel'fand-Cetlin polytope corresponding to the components of the degeneration of X_w are precisely those given by rc-graphs of Fomin-Kirillov. This is joint work with Ezra Miller.
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We present some explicit multiplication formulas in the Grothendieck ring of the variety of complete flags in Cⁿ, which generalize some well-known formulas in cohomology. Our formulas involve Grothendieck polynomials, which are representatives for Schubert classes in the Grothendieck ring. These formulas are concerned with: (1) the hyperplane section of a Schubert variety (a Monk type formula); (2) the restriction of a dominant line bundle to a Schubert variety; (3) the multiplication of an arbitrary Schubert class by a special one, which is pulled back from a Grassmannian projection (a Pieri type formula). We show the way in which formulas (1) and (2) are related by convolution inverse in a certain Hopf algebra. Different and more general formulas for (1) and (2) were given by A. Ram, H. Pittie, and M. Brion. Their formulas are in terms of Littelmann paths, and are only shown to hold in the Grothendieck ring. Our formulas are polynomial identities, and are in terms of chains in the Bruhat order on the symmetric group. The latter framework seems more suitable for multiplication problems in Schubert calculus, as shown by previous work in this area. The part of this work related to problem (3) is joint with F. Sottile.
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A theorem of Kim gives a presentation of the (small) quantum cohomology ring of the generalized flag manifold G/B. In order to have a complete picture of this ring, one needs a solution to the "quantum Giambelli problem", i.e. polynomial representatives of Schubert classes in Kim's ring. We present a general formula for such polynomials, which involves representatives of Schubert classes in Borel's description of H^*(G/B), divided difference operators and the coefficients of the "quantum Chevalley formula".
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Fix vector spaces V₀, ..., V_n, and consider the set Hom(V) of quivers V₀ --> ... --> V_n. Quiver cycles are subsets O_r of Hom(V) where the ranks of the composite maps V_i --> V_j are bounded above by specified integers r = r_ij for i < j. Buch and Fulton expressed the equivariant cohomology class [O_r] in terms of Schur functions, and conjectured a combinatorial formula for the coefficients. In particular, they conjectured that the coefficients, which directly generalize Littlewood-Richardson coefficients, are positive. In this ongoing project, we construct a flat family whose general fiber is isomorphic to O_r, and whose special fiber has components that are products of matrix Schubert varieties. This proves a formula for [O_r] in terms of Stanley symmetric functions (stable double Schubert polynomials) F_w indexed by lists w of n permutations. Our formula is obviously positive for geometric reasons, so it immediately implies positivity of the Buch-Fulton formula. Moreover, we conjecture that the special fiber is generically reduced, so that our coefficients all equal 1, and we propose a simple nonrecursive combinatorial characterization of which lists w appear. This is joint work with Allen Knutson and Mark Shimozono.
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The quantum Bruhat graph, which is an extension of the graph formed by covering relations in the Bruhat order, is naturally related to the quantum cohomology ring of G/B. We enhance a result of Fulton and Woodward by showing that the minimal monomial in the quantum parameters that occurs in the quantum product of two Schubert classes has a simple interpretation in terms of directed paths in this graph.

We define path Schubert polynomials, which are quantum cohomology analogues of skew Schubert polynomials recently introduced by Lenart and Sottile. They are given by sums over paths in the quantum Bruhat graph of type A. The 3-point Gromov-Witten invariants for the flag manifold are expressed in terms of these polynomials. This construction gives a combinatorial description for the set of all monomials in the quantum parameters that occur in the quantum product of two Schubert classes.
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For any complex semisimple lie group G, we know that in the ordinary cohomology ring H^*(G/B; Z), many of the structure constants (for the Schubert basis) vanish, and the rest are strictly positive. We present a combinatorial game which provides some criteria for determining which of these Schubert structure constants vanish. Although these criteria are not proven to cover all cases, in practice they work very well, giving a complete answer to the question for G = GL(7,C).
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We discuss an approach to Schubert Calculus based on a theory of quasideterminats of matrices with noncommutative entries developed by I. Gelfand and W. Retakh.
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The Peterson variety is a projective variety introduced by Dale Peterson that encodes the quantum cohomology rings of all partial flag varieties as coordinate rings coming from an affine paving. We will describe its `positive part' (in the sense of total positivity for matrices). This is related to Schubert bases and the positivity of structure constants in quantum Schubert calculus.
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In the lecture we approach the theory of Schur and Schubert polynomials from the point of view of generalized Thom polynomials, i.e. we realize these polynomials as equivariant Poincare duals of orbits of some representation. Then we can apply the author's method to compute them as Thom polynomials, thus we get new definitions for Schur and Schubert polynomials. Interestingly enough we will obtain them as unique solutions of linear equation systems. Other definitions for Schur and Schubert polynomials (e.g. the Lascoux-Schützenberger recursion) will be interpreted in this language. Along the way we also redefine the double Schubert polynomials and define "double Schur polynomials". We show how this approach is related to the structure of the cohomology ring of the Grassmannian, the flag manifold and other quotient spaces.
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From geometric considerations we construct Grothendieck polynomials in terms of chains in the Bruhat order on the symmetric group. We also give formulas for the specialization of a Grothendieck polynomial at two sets of variables in terms of Grothendieck polynomials in each set of variables, permutation patterns, and k-theory structure constants of flag manifolds.
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We discuss a number of results which show that the 3-point, genus zero, degree d Gromov-Witten invariants on a Grassmannian manifold X are equal to classical triple intersection numbers on a homogeneous space Y_d of the same Lie type as X. In the symplectic and orthogonal cases, X is the Grassmannian which parametrizes maximal isotropic subspaces of a vector space equipped with the corresponding nondegenerate bilinear form. Our theorems are proved using only basic algebraic geometry and can be applied to study the small quantum cohomology ring of X. This is joint work with Anders S. Buch and Andrew Kresch.
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In an attempt to provide an alternative concrete framework for studying the Schubert calculus of G/B, we describe a general construction for bases of the cohomology ring of G/B in terms of "special classes".
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In the GKM picture of the equivariant cohomology of flag varieties, a Schubert class S_w is regarded as a map (satisfying some compatibility conditions) that attaches a polynomial to each fixed point. The equivariant Schubert class S_w can be computed by applying a left divided difference operator (associated to a certain reduced word) to the top class, and the value S_w(u) is obtained by adding the (rational) contributions of certain subwords. For Grassmannians, these subwords correspond bijectively to fixed points for a torus action on a smooth manifold, and the computation of S_w(u) is equivalent to integrating an equivariant form over this manifold.